Positioning Measurements and Carrier Switching in Multi-Carrier Wireless Communication Networks

ABSTRACT

In a multi-carrier wireless communication network, positioning-aware switching of a primary carrier from a first carrier to a second carrier for a UE is constrained to enable one or more positioning measurements to be performed. Either the selection of the second carrier, the timing of switching from the first to the second carrier, or both, are constrained to enable and enhance the positioning performance. The constraints may be operative at a serving node of the network, at a UE, or both. Further constraints may be applied to the network to enhance positioning performance. Carrier switching may be across Radio Access Technology (RAT), and the positioning constraints may include configuring or re-configuring a device to perform positioning measurements in measurement gaps (e.g., on a secondary carrier in LTE systems when Positioning Reference Signals are not transmitted on the primary carrier).

RELATED APPLICATIOINS

This application is a continuation of U.S. patent application Ser. No.12/897,915 filed Oct. 5, 2010 which claims the benefit of U.S.Provisional Application Ser. No. 61/388,845 filed Oct. 1, 2010, thedisclosures of each of which are incorporated herein by reference intheir entirety.

TECHNICAL FIELD

The present invention relates generally to multi-carrier wirelesscommunication networks, and in particular to positioning-aware primarycarrier switching in multi-carrier networks.

BACKGROUND

The possibility of identifying user geographical location in wirelesscommunication networks has enabled a large variety of commercial andnon-commercial services, e.g., navigation assistance, social networking,location-aware advertising, emergency calls, and the like. Differentservices may have different positioning accuracy requirements imposed bythe application. In addition, regulatory requirements exist in somecountries on the positioning accuracy for basic emergency services,i.e., FCC E911 in US. Positioning methods include GPS or Assisted-GPS(A-GPS), for User Equipment (UE) or other devices which include a GPSreceiver circuit. Since not all UE are equipped to receive and processGPS ranging signals, other positioning methods have been standardized by3GPP, such as Observed Time Difference of Arrival (OTDOA), in which a UEmeasures the relative timing of reference signals transmitted fromdifferent base stations. The UE (or a location services network node)can then estimate the UE position based on the measured signal arrivaltimings.

An advance in wireless communication technology, which promises improvedbandwidth and higher signal quality, is multi-carrier transmission, inwhich two or more signals are modulated onto different carrierfrequencies and transmitted simultaneously. Generally, one carrierfrequency (or simply “carrier”) is designated as a primary carrier (alsoknown as the anchor carrier), and other carriers are consideredsecondary carriers (also known as component carriers). For loadbalancing and other network management reasons, a network may switch thecarriers for individual UEs—e.g., assigning a particular carrier as theprimary carrier for one or more UEs, and a secondary carrier for otherUEs. This carrier switching is dynamic, and may include switchingprimary carrier between different Radio Access Technologies (RAT), e.g.,between LTE and HSPA.

In prior art multi-carrier wireless communication networks, the impacton the positioning measurements is not considered in primary carrierswitching decisions. As a consequence, ongoing positioning measurementsmay be interrupted or delayed when carriers are switched. Furthermore,reference signals used in some positioning methods, such as OTDOA, arenot transmitted on all carriers. Accordingly, a UE's primary carriercould be switched from a carrier transmitting Positioning ReferenceSignals (PRS) to a carrier that does not transmit PRS, forcing the UE(or other device) to obtain positioning measurements in measurement gapson a secondary carrier. Positioning measurements obtained on a secondarycarrier may have less strignent requirements, may be inconsistent, andmay take longer to acquire and process than those obtained from aprimary carrier transmitting PRS. This can adversely affect both therapidity and quality/accuracy of UE positioning procedures.

SUMMARY

According to one or more embodiments described and claimed herein, in amulti-carrier wireless communication network, positioning-awareswitching of a primary carrier from a first carrier to a second carrierfor a UE is constrained to enable one or more positioning measurementsto be performed. Either the selection of the second carrier, the timingof switching from the first to the second carrier, or both, areconstrained to meet and further enhance the requested positioningperformance, where the positioning performance may be described by a setof positioning QoS parameters, such as horizontal or vertical accuracy.The constraints may be operative at a serving node of the network, at aUE, or both. Further constraints may be applied to the network toenhance positioning performance, such as selection of positioningprocedures when carrier switching additionally comprises Radio AccessTechnology (RAT) switching.

One embodiment relates to a method of positioning-aware carrierswitching for a UE, by a serving node of the UE in a multi-carrierwireless communication network. A first carrier is assigned as a primarycarrier for the UE. A second carrier is selected to be the primarycarrier for the UE. The primary carrier for the UE is switched from thefirst carrier to the second carrier. At least one of the selecting andswitching steps is constrained so as to enable one or more positioningmeasurements to be performed.

Another embodiment relates to a method of positioning-aware carrierswitching by a UE operative in a multi-carrier wireless communicationnetwork. Communication signals are received on a first carrier as aprimary carrier. One or more positioning measurements are performed. Anindication is received from a serving node that the primary carrier isto be switched from the first carrier to a second carrier. The primarycarrier is switched to the second carrier while preserving the ongoingpositioning measurements.

Still another embodiment relates to a serving node of a multi-carrierwireless communication network. The node includes a transceiveroperative to simultaneously transmit to a UE communication signalsmodulated onto two or more carriers, wherein a first carrier isdesignated as a primary carrier for a particular UE. The node alsoincludes a controller operative to control the transceiver, and furtheroperative to select a second carrier to be the primary carrier for theUE, and to control the transceiver to switch the primary carrier for theUE from the first carrier to the second carrier. The controller isfurther operative to constrain at least one of the selecting andswitching operations so as to enable one or more positioningmeasurements to be performed.

Yet another embodiment relates to a UE operative in a multi-carrierwireless communication network. The UE includes a transceiver operativeto simultaneously receive from a network node communication signalsmodulated onto two or more carriers, wherein a first carrier isdesignated as a primary carrier for the UE. The UE also includes aposition measurement function in data communications relationship to thetransceiver and operative to perform positioning measurements used inascertaining a geographic location of the UE. The UE further includes acontroller operative to control the transceiver and position measurementfunction, and further operative to switch from the first carrier to asecond carrier as the primary carrier in response to signals receivedfrom the network node, while preserving ongoing positioningmeasurements.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a functional block diagram of an Assisted-GPS positioningsystem in a multi-carrier wireless communication network.

FIG. 2 is a functional block diagram of an Observed Time Difference ofArrival positioning system in a multi-carrier wireless communicationnetwork.

FIG. 3 is a frame diagram depicting Positioning Reference Signalsassembled into sub-frames.

FIG. 4 is a time-frequency diagram of Positioning Reference Signals.

FIGS. 5A and 5B are frequency graphs showing aggregated spectrum in amulti-carrier wireless communication network.

FIG. 6 is a functional block diagram of a multi-Radio Access Technology,multi-carrier wireless communication network.

FIG. 7 is a flow diagram of a method of positioning-aware carrierswitching for a UE, by a serving node of the UE in a multi-carrierwireless communication network.

FIG. 8 is a flow diagram of a method of positioning-aware carrierswitching by a UE operative in a multi-carrier wireless communicationnetwork.

DETAILED DESCRIPTION Assisted-GPS Positioning

In many environments, user position in a wireless communication networkcan be accurately estimated by using positioning methods based on theGlobal Positioning Navigational System (GNSS) examples of which includethe Global Positioning System (GPS), Galileo, and the like. The GPS ispresently a fully operational GNSS system. Many modern User Equipments(UE) include GNSS or more specifically GPS receiver circuits. Inaddition, modern networks may assist UEs in order to improve theterminal receiver sensitivity and GPS start-up performance, known asAssisted-GPS positioning, or A-GPS. FIG. 1 depicts a representativeA-GPS multi-carrier wireless communication network 30. Both a UE 12 tobe positioned, and a fixed network GPS receiver 46, receive rangingsignals from a plurality of GPS satellites 20. A location servicesnetwork node 40, including a GPS interface 42, provides assistance data,such as satellite 20 ephemeral data, to the UE 12 via a core network 44and the UE's serving node 32 (e.g., an eNode-B). GPS or A-GPS receivers,however, may be not necessarily available in all wireless terminals.Furthermore, GPS is known to often fail in indoor environments and urbancanyons. A complementary terrestrial positioning method, called ObservedTime Difference of Arrival (OTDOA), has therefore been standardized by3GPP. Enhanced cell identity (E-CID) based positioning method is anotherexample of a terrestrial positioning method that has also beenstandardized by 3GPP.

Observed Time Difference of Arrival Positioning

FIG. 2 depicts a UE 12 measuring the timing differences for downlinkreference signals (depicted as dashed lines) received from multipledistinct locations in a multi-carrier wireless communication network.For each (measured) neighbor cell, the UE 12 measures the ReferenceSignal Time Difference (RSTD), which is the relative timing differencebetween each neighbor cell and the reference cell. The UE 12 positionestimate is then found as the intersection of hyperbolas correspondingto the measured RSTDs. At least three measurements from geographicallydispersed base stations with a good geometry are needed to solve for twocoordinates of the terminal and the receiver clock bias. In order tosolve for position, precise knowledge of the transmitter locations andtransmit timing offset is needed. The position calculation can beperformed by the UE 12 (UE-based positioning mode), or alternatively bya location services network node (UE-assisted positioning mode), such asthe Enhanced Serving Mobile Location Center (E-SMLC) or Secure UserPlane Location (SUPL) Location Platform (SLP) in the Long Term Evolution(LTE) 3GPP standard.

To enable positioning in LTE and facilitate positioning measurements ofa proper quality and for a sufficient number of distinct locations, newphysical signals dedicated for positioning, called Positioning ReferenceSignals (PRS) have been introduced, and low-interference positioningsub-frames have been specified in 3GPP. See the technical specification,3GPP TS 36.211, “Evolved Universal Terrestrial Radio Access (E-UTRA);Physical Channels and Modulation.”

Positioning Reference Signals

As explained in greater detail herein, in LTE systems, PRS aretransmitted from one antenna port (R6) according to a pre-definedpattern. A frequency shift, which is a function of Physical CellIdentity (PCI), can be applied to the specified PRS patterns to generateorthogonal patterns and modeling the effective frequency reuse of six,which makes it possible to significantly reduce neighbor cellinterference on the measured PRS, and thus improve positioningmeasurements. Even though PRS have been specifically designed forpositioning measurements and in general are characterized by bettersignal quality than other reference signals, the standard does notmandate using PRS. Other reference signals, e.g. cell-specific referencesignals (CRS), could in principle also be used for positioningmeasurements.

PRS are transmitted in pre-defined positioning sub-frames grouped byseveral consecutive sub-frames (N_(PRS)), known as one positioningoccasion. Positioning occasions occur periodically with a certainperiodicity of N sub-frames, i.e., the time interval between twopositioning occasions, as depicted in FIG. 3. In LTE, the standardizedperiods N are 160, 320, 640, and 1280 ms, and the number of consecutivesub-frames are 1, 2, 4, and 6.

In Universal Mobile Telecommunications System (UMTS) Terrestrial RadioAccess Network (UTRAN) Frequency Division Duplex (FDD) networks, SystemFrame Number (SFN)-SFN type 2 measurement performed by the UE 12 areused for the OTDOA positioning method. See the technical specification,3GPP TS 25.215, “Physical Layer Measurements (FDD).” This measurement isthe relative timing difference between cell j and cell i based on theprimary Common Pilot Channel (CPICH) from cell j and cell i. In UTRAN,the UE-reported SFN-SFN type 2 measurement is used by the network 30 toestimate the UE 12 position.

The OTDOA and other positioning methods such as enhanced cell ID (E-CID)are to be used also for emergency calls. Hence the response time ofthese measurements should be as low as possible to meet the emergencycall requirements.

As discussed above, in LTE, the PRS are transmitted from one antennaport (R6) according to a pre-defined pattern. The currently specifiedPRS patterns are depicted in FIG. 4, where the squares denoted R₆indicate PRS resource elements (REs) within a block of 12 subcarriersover 14 OFDM symbols (1 ms sub-frame with normal cyclic prefix). A setof frequency shifts can be applied to the pre-defined PRS patterns toobtain a set of orthogonal patterns which can be used in neighbor cellsto reduce interference on PRS and thus improve positioning measurements.The effective frequency reuse of six can be modeled in this way. Thefrequency shift is defined as a function of Physical Cell ID (PCI) asfollows,

v _(shift)=mod(PCI,6).

On a sub-frame basis, the PRS can also be transmitted with zero power,or can be muted.

To allow for detecting PRS from multiple sites and at a reasonablequality, positioning sub-frames have been designed as low-interferencesub-frames (LIS). In general, data transmission is suppressed inpositioning sub-frames. This means the Physical Downlink Shared Channel(PDSCH) shall not be transmitted to the UE 12 during the PRS sub-frames.Thus, in synchronous networks 30 PRS are ideally interfered only by PRSfrom other cells having the same PRS pattern index (i.e. same verticalshift v_(shift)) and not by the data transmissions.

In addition to the use of LIS, the PRS can also be transmitted duringthe sub-frames configurable for the Mobile Broadcast Single FrequencyNetwork (MBSFN). These sub-frames do not contain user data, and only thefirst two OFDM symbols in each MBSFN sub-frame may contain commoncontrol channels (e.g., PDCCH) or physical signals (e.g., CRS). In LTEup to 6 downlink sub-frames in a frame can be configured for the MBSFN.In MBSFN sub-frames, the PRS pattern is specified in 2GPP TS 36.211. Dueto absence of data transmissions, the interference is also reduced inthese MBSFN sub-frames.

Since for OTDOA positioning PRS signals from multiple distinct locationsneed to be measured, the UE 12 receiver may have to deal with PRS thatare much weaker than those received from the serving cell. Furthermore,without the approximate knowledge of when the measured signals areexpected to arrive in time, or the exact PRS pattern, the UE 12 wouldneed to do signal search within a large window, which would impact thetime and accuracy of the measurements as well as the UE 12 complexity.To facilitate UE 12 measurements, the network 30 transmits assistancedata to the UE 12, which includes, among other things, reference cellinformation, neighbor cell list containing PCIs of neighbor cells, thenumber of consecutive downlink sub-frames, PRS transmission bandwidth,frequency, and the like.

In LTE OTDOA, the UE 12 measures Reference Signal Time Difference (RSTD)which has been defined in the standard, i.e., 3GPP TS 36.214. Themeasurements are specified for both intra-frequency and inter-frequencyand conducted in the RRC_CONNECTED state.

Enhanced Cell ID Based Positioning

The E-CID based method typically relies on more than one UE and/or basestation measurements to determine the UE location. Examples of UEmeasurements in LTE are, e.g., cell identity reporting; UE Rx-Tx timedifference measurement, which is measured by the UE from the servingcell; RSRP; RSRQ; etc. The cell identity reporting, RSRP, and RSRQmeasurements are carried out by the UE from the serving and neighborcells. Examples of base station (e.g., eNode B) measurements which areperformed by the base station on the signals transmitted by the UE are,e.g., BS Rx-Tx time difference measurement; angle of arrival (AoA);Timing Advanced (TA) etc. The positioning node (e.g., E-SMLC in LTE)uses any combination of these measurements to determine the location ofthe UE 12.

Measurement Gaps

The UE 12 performs inter-frequency and inter-RAT measurements inmeasurement gaps. The measurements are done for various purposes:mobility, positioning, self organizing network (SON), minimization ofdrive tests, and the like. Furthermore the same gap pattern is used forall types of inter-frequency and inter-RAT measurements. Therefore,E-UTRAN must provide a single measurement gap pattern with constant gapduration for concurrent monitoring (i.e., cell detection andmeasurements) of all frequency layers and RATs. The E-UTRAN UE 12supports two configurations consisting of the maximum gap repetitionperiod (MGRP) of 40 and 80 ms; both with the measurement gap length of 6ms. In practice, due to frequency switching time, less than 6sub-frames, but at least 5 full sub-frames, are available formeasurements within each such measurement gap.

In LTE, measurement gaps are configured (and re-configured as necessary)by the network 30 to enable measurements on the other LTE frequenciesand/or other RATs (e.g., UTRAN, GSM, CDMA2000, etc). The gapconfiguration is signaled to the UE 12 over Radio Resource Control (RRC)protocol as part of the measurement configuration. Only one gap patterncan be configured at a time, and the network must re-configure the UE 12to change the gap pattern. The same pattern is used for all types ofconfigured measurements, e.g., inter-frequency neighbor cellmeasurements, inter-frequency positioning measurements, inter-RATneighbor cell measurements, and inter-RAT positioning measurements.

In a multi-carrier LTE network 30, the measurement gaps may still beused for performing measurements on other RATs (e.g., GSM, UTRAN) or onnon-configured LTE carrier frequencies (i.e., carriers not configured byRRC). The mobility measurements in LTE require UE 12 to performmeasurements over the synchronization signals, i.e., primarysynchronization signals (PSS) and secondary synchronization signals(SSS), and cell-specific reference signals (CRS) to enableinter-frequency handover and enhance system performance. Examples of LTEmobility measurements are Reference Signal Received Power (RSRP) andReference Signal Received Quality (RSRQ).

In UTRAN FDD, the measurements on other UTRAN FDD carriers and on otherRATs (e.g., LTE, GSM etc) are carried out in compressed mode (CM) gaps,which occur periodically. For example a CM gap pattern may consist of 10UTRAN FDD slots (1 slot=0.67 ms) gap occurring every 2^(nd) frame (1frame=10 ms). One main difference between UTRAN FDD and LTE is that inthe former one CM pattern is used for each carrier, e.g., 2 CM patternsfor measuring on two different UTRAN FDD carriers.

In multi-carrier High Speed Packet Access (HSPA) systems, depending uponthe UE 12 capability, the CM gap pattern may still be required formeasuring on other RATs and on other UTRAN FDD carriers.

Multi-Carrier Networks

A multi-carrier wireless communication network—also known as carrieraggregation (CA) or, e.g., Dual Cell (DC)—allows the UE 12 tosimultaneously receive and/or transmit data over more than one carrierfrequency. Each carrier frequency is often referred to as a componentcarrier (CC) or simply a serving cell in the serving sector, morespecifically a primary serving cell or secondary serving cell. Themulti-carrier concept is used in both HSPA and LTE.

In an intra-RAT multi-carrier system (also known as single RATmulti-carrier system), all the component carriers belong to the sameRAT, e.g., LTE FDD multi-carrier system, LTE TDD multi-carrier system,UTRAN FDD multi-carrier system, or UTRAN TDD multi-carrier system. InLTE multi-carrier systems, it is possible to aggregate a differentnumber of component carriers, of different bandwidths and possibly indifferent frequency bands, in the uplink (UL) and the downlink (DL), asdepicted in FIG. 5. FIG. 5A depicts an aggregated bandwidth of 90 MHz,comprising four 20 MHz carriers and one 10 MHz carrier. In FIG. 5A, allof the carriers are contiguous in frequency. FIG. 5B depicts anaggregated bandwidth of 20 MHz, comprising four non-contiguous carriersof 5 MHz each.

In a multi-carrier system, one of the component carriers is called theprimary carrier or anchor carrier, and the remaining ones are calledcomponent carriers or secondary/supplementary carriers. The primary andsecondary carriers are sometimes referred to in the art as the primaryserving cell and secondary serving cell, respectively. The primarycarrier carries all common and UE-specific control channels. Thesecondary carrier may contain only necessary signaling information andsignals, e.g., those that are UE-specific may be not present in thesecondary carrier, since both primary uplink and downlink carriers aretypically UE-specific. This means that different UEs 12 in a cell mayhave different downlink primary carriers. Same is true for the uplinkprimary carriers. For example, in a multi-carrier system consisting of 2DL carriers (F1_DL, F2_DL) and 2 UL carriers (F1_UL, F2_UL), some of theUEs 12 may be assigned F1_DL as the primary carrier, and remaining onesmay have F2_DL as their primary carrier. The network is able to changethe primary carrier of any UE 12 at any time. This is done, for example,to balance the load on different carriers.

The simultaneous transmission and/or reception of multiple carriersenable the UE 12 to significantly increase its data transmission and/orreception rates. For example, 2×20 MHz aggregated carriers in LTEmulti-carrier system would theoretically lead to a two-fold increase indata rate, compared to that attained by a single 20 MHz carrier.

In LTE advanced, several contiguous and non-contiguous carrieraggregation scenarios are being considered. For example, in onescenario, five contiguous component carriers, each of 20 MHz (i.e., 5×20MHz) is being considered for LTE TDD. Similarly, for LTE FDD, a scenarioconsisting of four contiguous component carriers, each of 20 MHz (i.e.,4×20 MHz) in the downlink and two contiguous component carriers in theuplink, is being studied.

In an inter-RAT multi-carrier system (also known as multi-RATmulti-carrier system), the component carriers may belong to differentRATs in both uplink and downlink. For example, in such systems onecomponent carriers may belong to LTE FDD and another one to LTE TDD. Asanother example, component carriers may belong to UTRAN FDD and E-UTRANFDD. In such systems, one of the RATs may be considered as the main orprimary RAT while the remaining ones are the auxiliary RATs. The anchoror primary carrier may typically belong to the primary RAT.

FIG. 6 depicts a functional block diagram of a multi-RAT, multi-carrierwireless communication network 10. A UE 12 receives and transmitscommunication and control signals, modulated onto two or more carrierfrequencies, according to a first RAT 30, from and to a serving node 32in the first RAT 30, such as an eNode B in LTE. The serving node 32comprises a multi-carrier transceiver 34 and a controller 38 operativeto select a primary carrier and one or more secondary carriers for theUE 12, and further operative to switch the primary carrier as requiredor desired for optimal multi-carrier network operation. According toembodiments of the present invention, the controller 38 is constrainedin its primary carrier selection and switching decisions in apositioning-aware manner, as described further herein, such that, e.g.,ongoing positioning measurements are completed. The serving node 32 isconnected, via a network interface 36, to a location services node 40,such as E-SMLC or SLP in LTE. The location services node 40 may performpositioning procedures for a UE 12 based on positioning measurementsperformed by the UE 12, such as GPS signal reception or OTDOAmeasurements of PRS.

The UE 12 additionally receives and transmits communication and controlsignals, modulated onto two or more carrier frequencies, according to asecond RAT 50, from and to a serving node 52 in the second RAT 50. Theserving node 52 is additionally connected to a location services node54.

The UE 12 includes a multi-carrier transceiver 14 operative tosimultaneously receive and/or transmit communication and control signalsmodulated onto two or more different carrier frequencies, under thecontrol of a controller 18. The UE 12 additionally includes a positionmeasurement function 16 operative to perform positioning measurements.The positioning measurements may, for example, comprise the receipt andprocessing of navigation signals from a satellite 20 (e.g., GPS), or maycomprise the timing of PRS received by the transceiver 14 from aplurality of base stations 32, 52. The positioning measurement function16 may further calculate estimates of the UE 12 position, or maytransmit positioning measurements via the transceiver 14 to a locationservices node 40, 54 for position calculation. According to embodimentsof the present invention, the controller 18 operates in apositioning-aware manner, as described further herein, such that, e.g.,ongoing positioning measurements are completed.

Those of skill in the art will recognize that the controllers 18, 38 maycomprise appropriately programmed processors or Digital SignalProcessors (DSP). Furthermore, functional blocks, such as the positionmeasurement function 16, may be implemented, in various embodiments, ashardware circuits (such as ASIC), as programmable logic circuits (e.g.,FPGA) with appropriate firmware, as software modules executing on aprocessor such as the controller 18, or any combination of the above.

As discussed above, prior art multi-carrier wireless communicationnetworks 10, whether intra-RAT or inter-RAT, do not consider the impacton positioning measurements when changing the primary carrier for a UE12. Consequently, positioning measurements may be interrupted ordelayed.

Another consequence of not considering positioning procedures whenswitching primary carriers is that a UE 12 may have to perform thepositioning measurements in gaps or compressed mode pattern, e.g., if noPRS are available on the new primary carrier. The positioningmeasurements in gaps, which may have to be done on the secondarycarrier, lead to longer delay and worse accuracy compared to thatperformed on the primary carrier. Furthermore, the network may need tore-configure the UE 12 for a new gap pattern, increasing signalingoverhead.

Furthermore, the measurement requirements of UE measurements performedover the secondary component carriers (whether in measurement gaps ornot) are less stringent compared to those done on the primary carrier.For example when a component carrier is deactivated, the measurementperiod of the measurement quantity becomes longer. This degradesperformance. Additionally, the measurement results may be inconsistentwhen performing measurements over the secondary carrier, especially ifthe component carrier is frequently activated and deactivated.

According to embodiments of the present invention, carrier switchingdecisions in a multi-carrier wireless communication network 10 areconstrained to ensure consistent and robust positioning measurementperformance. These constraints may impact the selection carrierfrequencies to be assigned to a UE 12 as a primary or secondary carrier,and/or may also impact the timing of the carrier switching. Theseconstraints may operate on the serving network node 32, 52 (e.g.,eNode-B), and/or the UE 12. For example, constraints may be imposed toensure that switching the primary carrier occurs either prior tostarting positioning measurement session or after the ongoingpositioning measurement session is complete—i.e., that no primarycarrier switching occurs during a positioning session or measurementperiod. As another example, primary carrier selection from among thecomponent carriers may be constrained to select a carrier which transmitthe PRS for enabling the UE 12 to perform positioning measurements—i.e.,selecting a primary carrier having the most favorable configuration ofPRS that can be used for positioning measurements (e.g., the one whichtransmits the largest density of PRS in time and/or frequency domains),or the carrier having the best possible propagation characteristics.

As further examples, constraints may trigger the transmission of PRS forpositioning on a component carrier in response to the number of usersfor which the carrier is the primary carrier; selecting a positioningmethod in an inter-RAT, multi-carrier network 10 so as to avoid the needfor gaps or compressed mode pattern; switching between positioningmethods in an inter-RAT, multi-carrier network 10 when changing theprimary carrier/RAT so as to avoid the need for gaps or compressed modepattern; or signaling to other network nodes 40, 54 (e.g., locationservices nodes such as E-SMLC or SLP) about the primary carrier/RATcurrently assigned to a UE 12.

In general, the positioning session is not limited to any specificmethod, but rather refers to any relevant method that require the UE 12to perform positioning related measurements, such as OTDOA, E-CID, andthe like. However, some embodiments relate to OTDOA, which requirespositioning measurements on the PRS. Embodiments of the presentinvention impose constraints on the following aspects of primary carrierselection/switching operations:

Primary carrier switching procedures;

Primary carrier switching occasion;

Reconfiguring measurement gaps triggered by switching the primarycarrier;

Primary carrier selection criteria;

Enabling of reference signals for positioning on a component carrier;

Enabling carrier hopping for enhancing positioning performance;

Positioning method selection in inter-RAT multi-carrier system;

Positioning method switching in inter-RAT multi-carrier system; and

Signaling of primary carrier information to positioning node.

Primary Carrier Switching Procedures

In one embodiment, the primary carrier switching operation is viewed asa type of handover procedure. For example, when a location service (LCS)session is ongoing, the primary carrier switching procedure follows therules that apply for handover. In a further example, a positioningsession is interrupted and restarted at handover.

Other embodiments constrain the switching of the primary carrier in apositioning-aware manner. The constrains may comprise one or more of thefollowing:

Activating monitoring of positioning-related communications;

Deciding the primary carrier switching occasion, as discussed furtherherein;

Deciding the primary carrier, as discussed further herein;

Configuration/re-configuration procedures optimizing positioningperformance, which may be triggered by carrier switching, such asconfiguring/re-configuring measurement gaps; changing the positioningconfiguration of a carrier; or switching positioning method.

To enable positioning-aware carrier switching, the network node 32, 52responsible for the primary carrier switching (e.g., eNode B inintra-LTE multi-carrier) has to be aware of whether there is an on-goingpositioning session for the specific UE 12 or not. If the network node32, 52 does not have any explicit information about whether or not thereis an on-going positioning session for a certain UE 12, the attempt toswitch the primary carrier may trigger one or more actions in thenetwork node 32, 52 in order to obtain this information. Such actionsmay include extracting information by reading signaling messages (e.g.,by sniffing other protocols which carry the information to/from thespecific UE 12 and pass over the network node 32, 52 transparently);requesting the information from another node 40, 54 such as a locationservices network node (e.g., E-SMLC or SLP in LTE) or a network nodecontrolling mobility procedures (e.g., MME in LTE); or requestinginformation from the UE 12.

In one embodiment, a UE 12 sends a message to a location servicesnetwork node 40, 54 (e.g. E-SMLC) and/or radio network node 32, 52(e.g., eNode B) indicating that an ongoing positioning session isaborted or terminated prematurely due to a primary carrier switch. Inanother embodiment, the UE 12 sends a message to the positioning node40, 54 (e.g. E-SMLC) and/or radio network node 32, 52 (e.g., eNode B)indicating that it has switched the primary carrier while continuing theongoing positioning session. It is then up to the network 10 (e.g.E-SMLC 40, 54) whether to send updated assistance data to the UE 12 forpositioning measurements, or alternatively the network 10 can ask UE 12to abort the ongoing positioning session. This embodiment may beparticularly applicable to UE 12 which can perform positioningmeasurements on a secondary carrier without gaps, or if there are PRStransmitted on the new primary carrier. The UE 12 can acquire thisinformation (i.e., whether the new primary carrier transmits PRS or not)from the assistance data, which is either old assistance data or newdata sent after the primary carrier is switched.

The UE 12 behavior in these embodiments can be according to pre-definedrules. For example, one rule may state that the UE 12 shall abort anongoing positioning procedure if the primary carrier is changed duringthe positioning session. Another rule may state that the UE 12 shallperform the primary carrier switch even if there is an ongoingpositioning session, and continue the session. Yet another rule maystate that the UE 12 shall perform the primary carrier switch even ifthere is an ongoing positioning session, and continue the session onlyif certain conditions are met—e.g., if the PRS are available and/or theUE 12 has updated assistance data.

In one embodiment, the UE 12 does not switch the primary carrier untilthe ongoing positioning session is completed. The UE 12 may also send amessage to the network 10 (e.g., E-SMLC, eNode B) indicating that thereis an ongoing positioning session and the primary carrier switchingcannot be performed. In another embodiment, the UE 12 sends a message tothe network 10 indicating that the primary carrier switch will bedelayed until the positioning session is completed. In this case, the UE12 may also indicate a time until which the primary carrier switching isdelayed. The UE 12 behavior for these embodiments can be pre-defined,e.g., the UE 12 shall not perform the primary carrier switching whilethere is an ongoing positioning session, or the UE 12 shall perform theprimary carrier switching after the completion of the ongoingpositioning session. In one embodiment this may only apply to specificlocation services, e.g., emergency positioning or calls.

Primary Carrier Switching Occasion

Several types of positioning measurements—such as OTDOA RSTD in LTE orUTRAN FDD SFN-SFN type 2—are time critical, as they are typically usedfor emergency calls. In one embodiment, the network node 32, 52 (e.g.eNode B, RNC, etc.) responsible for switching or changing the primarycarrier is constrained from switching the carrier during an ongoingpositioning measurement session.

In one embodiment, the carrier switching is performed before the startof the positioning measurement session, e.g., prior the positioningsession, the network node 32, 52 responsible for the switching checkswhether carrier switching may be needed within a certain time (e.g., theestimated time for the positioning session or some pre-configured time).In another embodiment, the carrier switching is performed after thetermination of the positioning measurement session, i.e., the carrierswitching is postponed. This avoids interruption or delay in thepositioning measurements.

Additional factors may also be taken into account in the primary carrierswitching decision—that is, in deciding when to switch the primarycarrier. First, the LCS session duration or the time elapsed since theLCS request may be considered. In this embodiment, the measurementsession can be interrupted if the elapsed time does not exceed a certainthreshold. Some special cases are i) infinity as one special case, i.e.,primary carrier switching can always interrupt a positioning measurementsession, and ii) zero as another special case, i.e., primary carrierswitching never interrupts a positioning measurement session, but rathermust always wait until the completion of the session.

Another factor may be the requested positioning performance, which maybe measured by one or more metrics, such as horizontal accuracy,vertical accuracy, reporting time, and the like. Each of these metrics,or combinations thereof, may be compared to an appropriate positioningperformance threshold to determine whether the requested positioningperformance is met. In this embodiment, constraints apply to the primarycarrier switching decision depending on the type of positioning requestor measurement. For example, the primary switching constraints may beapplicable only to the time-critical positioning requests (e.g.,emergency calls) and may be relaxed for non-time critical requests(e.g., location requests). The constraints may not apply toaccuracy-critical requests when the switching can provide a higherpositioning accuracy. In case of non-critical requests, an abort messagecan then be sent, e.g. by UE 12 in case of a change of the primarycarrier, while there is an ongoing positioning measurement session.

Reconfiguring Measurement Gaps Triggered by Switching the PrimaryCarrier

When the primary carrier changes (for positioning or non-positioningreasons) and positioning measurements on the secondary carrier can onlybe performed in measurement gaps or compressed gap patterns, then theremay be a need to align the measurement gap with the transmission of PRSon the new secondary carrier, given that the gaps have been alreadyconfigured for that UE 12. Aligning the measurement gap with PRS meansthat a sufficient number of PRS fall within the measurement gaps tofacilitate positioning measurements (i.e., inter-frequency measurementswhich are typically done in the gaps).

Also, a pre-defined measurement gap pattern may be configured by thenetwork node 32, 52 if the primary carrier change would cause the UE 12to perform positioning measurements in the measurement gaps, e.g., if UE12 will have to do to inter-frequency measurement. For example, the UE12 may be configured with a specific measurement gap pattern for doingmeasurements (e.g., measurement gap pattern #0 in LTE, defined in 3GPPTS 36.133 and 3GPP TS 36.331 as 6 ms gaps occurring every 40 ms). Asanother example, the UE 12 may be re-configured with a specificmeasurement gap pattern for doing measurements (e.g., measurement gappattern #0 in LTE) in case a different gap pattern is currently used(i.e. prior to the primary carrier switch).

The scenario in which the UE 12 has to use the measurement gaps for themeasurements may occur if the PRS are not transmitted on the new primarycarrier, but they are instead transmitted on the old primary carrier,which has become the new secondary carrier after the carrier switch. Anexample of the specific measurement gap pattern is the gap pattern #0defined in 3GPP TS 36.133. Such a rule to use a specific measurement gappattern when primary carrier is switched can be pre-defined. The networknode 32, 52, e.g., eNode B will have to configure or re-configure thepre-defined gap pattern and the UE 12 will have to use this pre-definedgap pattern for the measurements.

In another embodiment a pre-defined rule may by that a multi-carriercapable UE 12 uses the measurement gaps or a specific measurement gappattern (e.g., pattern #0) for performing the positioning measurementswhen the PRS for performing the positioning measurements are nottransmitted on the primary carrier in a multi-carrier system.Alternatively, a pre-defined rule may be that a multi-carrier capable UE12 performs the positioning measurements without measurement gaps on theprimary carrier provided the PRS are transmitted on the primary carrier.

In another embodiment a pre-defined rule may be that after the downlinkprimary carrier is changed, a multi-carrier capable UE continuesperforming the positioning measurements without measurement gaps on thenew primary carrier provided the PRS are transmitted on the new primarycarrier.

In another embodiment a pre-defined rule may be that after the downlinkprimary carrier switch, in case the PRS are transmitted on the primarycarrier and at least on one secondary carrier, then a multi-carriercapable UE 12 continues performing the positioning measurements withoutmeasurement gaps on the new primary carrier.

Primary Carrier Selection Criteria

In a multi-carrier network 10 all component carriers may not transmitthe reference signals for performing the positioning measurements,notably OTDOA measurements, e.g., OTDOA RSTD in LTE.

In the prior art, the new primary carrier is selected without any regardto the presence or absence of the positioning reference signals, evenfor location services known to use the positioning references signals.This has a consequence of either the UE 12 has to continue thepositioning measurements in gaps after the primary carrier is changed incase the new primary carrier does not contain the positioning referencesignals, or the UE has to perform positioning measurements on otheravailable signals or on any normal pilot signals, e.g., CRS in LTE. Theuse of CRS for positioning measurements is possible but may lead topossible quality degradation and worse positioning accuracy.

In one embodiment, the network node 32, 52 is constrained in itsselection of a primary carrier to select a new primary carrier thatcontains the PRS. In addition, when selecting the new primary carrier,the network node 32, 52 may have additional constraints.

One such constraint may be selecting a primary carrier that has the mostfavorable reference signal configuration in time and/or frequency domain(e.g., presence of PRS vs. CRS only, larger PRS bandwidth, shorter PRSperiodicity, more consecutive positioning sub-frames in a positioningoccasion, etc.). This will improve positioning measurement qualityand/or lead to shorter measurement time.

Another primary carrier selection constraint may be selecting a primarycarrier that has better radio conditions, e.g., 900 MHz instead of 2 GHzin case both contain the positioning reference signals. This will ensurebetter positioning measurement quality.

Still another primary carrier selection constraint may be selecting aprimary carrier that transmits PRS (or transmits PRS within certainparameters) if the UE 12 uses at least certain specific client types orservice types related to positioning.

An LCS Client is defined as a software and/or hardware entity thatinteracts with a LCS Server for the purpose of obtaining locationinformation for one or more UEs. LCS Clients subscribe to LCS in orderto obtain location information. LCS Clients may or may not interact withhuman users. The LCS Client is responsible for formatting and presentingdata and managing the user interface (dialogue). The LCS Client mayreside in the UE 12 or SUPL-Enabled Terminal (SET), but it could also beon the network side (e.g., network maintenance services or base stationspositioning themselves). The Client Type information is very importantin practice since it allows for configuring LCS QoS discrimination in aflexible way. The following Client Types exist in UTRAN and E-UTRAN:Emergency Services, Value Added Services, PLMN Operator Services, LawfulIntercept Services, PLMN Operator Broadcast Services, PLMN OperatorOperation and Maintenance Services, PLMN Operator Anonymous StatisticsServices, and PLMN Operator Target MS Services Support. One example ofselective carrier switching based on Client Type is: select as theprimary carrier only a carrier with a large enough (e.g. >=5 MHz) PRStransmission bandwidth when the Client Type corresponds to emergencyservices, and allow switching to carriers with 1.4 MHz bandwidth forcommercial services.

Service Type is an attribute of specific LCS that may be provided by theLCS client. The LCS Client may also provide the service identity, whichcan then be mapped by the server to a certain Service Type which mayalso be verified against the LCS profile and the subscription.

Enabling of Reference Signals for Positioning on a Component Carrier

All component carriers in a network 10 may not be transmitting thepositioning reference signals. Therefore a situation may arise when anumber of UEs 12 interested in positioning are assigned the same primarycarrier, which does not currently transmit the positioning referencesignals. In the prior art, the network node or the positioning nodewould have to configure measurement gaps or compressed mode gaps toperform the positioning measurements on a secondary carrier thattransmits the positioning reference signals.

In one embodiment, if more than K users have the same primary carrier,and that carrier is not currently transmitting the reference signals forpositioning, then the network node 32, 52 (e.g. eNode B) initiates thetransmission of the reference signals for positioning. As a generalrule, the K users may be any type of users. However as a special casethe number of K users may belong to a certain class (e.g. low, medium orhigh priorities) and/or using a certain service type and/or having acertain client type.

In one embodiment, in order to reduce the reference signal overhead, thetransmission of the reference signals on a particular component carriermay be terminated when certain conditions are met. For example if lessthan L users have the same primary carrier, and that carrier iscurrently transmitting the reference signals for positioning, then thenetwork node 32, 52 (e.g. eNode B) may stop the transmission of thereference signals for positioning on the carrier. As a general rule, theL users may be any type of users. However as a special case the numberof L users may belong to a certain class (e.g. low, medium or highpriorities) and/or using a certain service type and/or having a certainclient type.

Carrier Hopping for Positioning

Positioning occasions, when the positioning reference signals aretransmitted, occur sparsely in time (e.g., 3GPP TS 36.211 specifies PRSperiodicity of minimum 160 ms and maximum 1280 ms). However, differentcomponent carriers may have different configurations. In an embodimentwherein a multi-carrier network 10 transmits PRS on more than onecomponent carrier, the positioning occasions are shifted in time ondifferent carriers, so that more than one positioning occasion becomesavailable over several carriers within the PRS period, e.g., more thanone positioning occasion in 160 ms PRS periodicity. A certain patterncan be applied for such multi-carrier PRS configurations, e.g., 40 msstep or time shifting between positioning occasions among carriers in afour-carrier system, with 160 ms PRS periodicity in each carrier. The UE12 conducting positioning measurements, instead of measuring inmeasurement gaps, hops between the carriers to avoid using the gaps.That is, the UE 12 measures PRS on a component carrier, which does notrequire gap. In one embodiment hopping implies temporarily switching theprimary carrier (e.g., at least for positioning measurements) so thatafter a certain period the UE 12 returns to the original primarycarrier.

Positioning Method Selection in Inter-RAT Multi-carrier Network

In one embodiment, a positioning method is selected depending upon themain or primary RAT and the primary carrier, with which a dynamic set ofavailable positioning methods is associated. In a multi-carrier network10 the inter-RAT positioning measurements are performed in gaps or usingCM pattern. In this embodiment, at least on one carrier, the positioningmeasurements are performed without the need for measurement gaps or CMpattern.

For example, consider a multi-carrier HSPA/LTE network 10. If the mainor primary carrier belongs to the LTE, and OTDOA is supported andconfigured by the network 10, and OTDOA is supported by the UE 12, thenOTDOA RSTD measurements are configured for the UE 12. On the other hand,if the primary carrier belongs to UTRA FDD, then OTDOA SFN-SFN type 2measurements are configured for the UE 12.

As another example, consider a GSM/LTE multi-carrier network 10. In GSMthe equivalent of OTDOA based method is called enhanced observed timedifference (E-OTD). The E-OTD relies on the Reference Time Difference(RTD) measurements performed by the UE 12 over signals transmitted bythe GSM Base Transceiver Station (BTS). If the primary carrier belongsto the GSM, and E-OTD is supported, then E-OTD RTD measurements areconfigured for the UE 12. Otherwise (i.e., when primary carrier is LTE),then the LTE OTDOA RSTD measurements are configured for the UE 12.

These examples may be generalized to inter-RAT multi-carrier networks 10including three or more RATs, e.g., GSM/HSPA/LTE. As a general rule, theOTDOA measurements pertaining to the RAT that is used in the primarynetwork 30, 50, are configured in a UE 12 for performing OTDOApositioning measurements.

Positioning Method Switching in Inter-RAT Multi-carrier Network

In an inter-RAT, multi-carrier network 10, the primary and secondarycarriers that belong to different RAT (e.g. LTE and HSPA) may be changedat any time. In one embodiment, when changing the main carrier, thepositioning method is also changed. A positioning method is selectedfrom the dynamic set of available positioning methods corresponding tothe RAT of the primary carrier, e.g., LTE OTDOA if the primary carrierbelongs to LTE and the desired method is a TDOA-like method.

Signaling of Primary Carrier Information to Location Services NetworkNode

In order to perform various actions by the network 10 and/or a locationservices node 40, 54, in one embodiment the network node 32, 53 thatswitches the primary carrier in an intra-RAT or inter-RAT multi-carriernetwork 10 signals the location services node 40, 54 (e.g., E-SMLC) orthe node controlling mobility (e.g., MME which then in turn informsE-SMLC) about the primary carrier/RAT used by the UE 12. The networknode 32, 52 may also signal a potential list of the primarycarriers/RATs that can be assigned to the UE 12.

In one embodiment, the UE 12 may also signal the location services node40, 54 (e.g. E-SMLC) about the primary carrier/RAT used by the UE 12.For example, the UE 12 can inform the location services node 40, 54(e.g. E-SMLC) at the start of the positioning session, when reportingits capabilities, or during the session. The UE 12 may signal thisinformation to the location services node 40, 54 upon receiving arequest from any network node 32, 52, 40, 54, e.g., E-SMLC, eNode B,etc.

FIG. 7 depicts a method 100 of positioning-aware carrier switching forUE 12, by a serving node 32, 52 of the UE 12 in a multi-carrier wirelesscommunication network 12. The serving node 32, 52 assigns a firstcarrier as a primary carrier for the UE 12 (block 102), and transmits tothe UE 12 communication and control signals modulated onto the firstcarrier frequency. The serving node 32, 52 selects a second carrier tobe the primary carrier for the UE 12 (block 104), and switches theprimary carrier for the UE 12 from the first carrier to the secondcarrier (block 106). In various embodiment, either the new primarycarrier selection (block 104), or the switching of the primary carrierfrom the first to the second carrier (block 106), or both, areconstrained so as to enable one or more positioning procedures todetermine the geographic position of the UE 12.

The constraints are described in detail above. Briefly, the new primarycarrier selection (block 104) may be constrained to select a carrierthat transmits PRS, or that has more favorable configuration of PRS, ormore favorable transmission characteristics, etc. Similarly, the primarycarrier switching (block 106) may be constrained by being delayed untilan ongoing measurement procedure completes, by performing the switchingprior to beginning a positioning procedure, by the type or QoS of therequested positioning procedure, and the like. Other constraints includereconfiguring measurement gaps in the UE 12 to accommodate a primarycarrier switch, enabling/disabling PRS transmission on one or morecarriers, configuring PRS transmissions to enable carrier hopping,aligning positioning methods with RATs, signaling carrier/RATinformation to network nodes 40, 54, and the like, as described ingreater detail herein above.

FIG. 8 depicts a method 200 of positioning-aware carrier switching by aUE 12 operative in a multi-carrier wireless communication network 10.The UE 12 receives communication signals from the network 10 on a firstcarrier as a primary carrier (block 202). The UE 12 performs one or morepositioning measurements (block 204), such as OTDOA measurements on PRS,receipt and processing of GPS signals, or the like. The UE 12 mayperform a positioning procedure using the positioning measurements, oralternatively may transmit the positioning measurements to a locationservices network node 40, 54 for the positioning procedure. The UE 12then receives an indication from a serving node 32, 52 that the primarycarrier is to be switched from the first carrier to a second carrier(block 206). The UE 12 switches to the second carrier as the primarycarrier while preserving the ongoing positioning measurements (block208). In various embodiments, this may entail delaying the switch to thesecond carrier until the positioning measurements are complete,suspending the positioning measurements and restarting them on the newprimary carrier, transmitting information about the primary carrierswitch to other network nodes 40, 52, and the like, as described ingreater detail herein above.

By implementing positioning-aware constraints on primary carrierswitching in a serving node 32, 52 and/or UE 12 of a multi-carrierwireless communication network 10, interruption and delay in obtainingpositioning measurements may be avoided. This enables positioningmeasurements with better accuracy and in shorter time period, both ofwhich may be critical for many applications, such as emergency calls.Embodiments of the present invention also enable faster positioningmeasurements and better accuracy in inter-RAT multi-carrier networks 10.

Embodiments of the present invention are applicable to any type of UE(e.g., cell phone, USB, wireless broadband module, target device orwireless relay node, etc.) which is capable of performing the relevantpositioning measurements for the purpose of determining a position.

The present invention may, of course, be carried out in other ways thanthose specifically set forth herein without departing from essentialcharacteristics of the invention. The present embodiments are to beconsidered in all respects as illustrative and not restrictive, and allchanges coming within the meaning and equivalency range of the appendedclaims are intended to be embraced therein.

What is claimed is:
 1. A method of positioning-aware carrier switchingfor User Equipment (UE), by a serving node of the UE in a multi-carrierwireless communication network, comprising: assigning a first carrier asa primary carrier for the UE; selecting a second carrier to be theprimary carrier for the UE; and switching the primary carrier for the UEfrom the first carrier to the second carrier; wherein at least one ofthe selecting and switching steps is constrained so as to enable one ormore positioning measurements to be performed.
 2. The method of claim 1wherein switching the primary carrier for the UE from the first carrierto the second carrier comprises treating the carrier switch as ahandover procedure for an ongoing location service session.
 3. Themethod of claim 1 wherein switching the primary carrier for the UE fromthe first carrier to the second carrier comprises: ascertaining whetherpositioning measurements for the UE are ongoing; and delaying switchingthe primary carrier for the UE from the first carrier to the secondcarrier until the positioning measurements are complete.
 4. The methodof claim 3 wherein delaying switching the primary carrier comprisesdelaying switching the primary carrier only if the requested positioningperformance exceeds a predetermined performance threshold.
 5. The methodof claim 1 further comprising configuring measurement gaps on the secondcarrier to align the UE measurement occasions with transmissions ofsignals on the second carrier used for positioning measurements.
 6. Themethod of claim 1 wherein selecting a second carrier to be the primarycarrier for the UE comprises selecting a second carrier that transmitsPositioning Reference Signals (PRS).
 7. The method of claim 1 furthercomprising, if at least a first predetermined number of UEs are assignedthe second carrier as a primary carrier, transmitting PositioningReference Signals (PRS) on the second carrier.
 8. The method of claim 1further comprising, if fewer than a second predetermined number of UEsare assigned the second carrier as a primary carrier, ceasing thetransmission of Positioning Reference Signals (PRS) on the secondcarrier.
 9. The method of claim 1 further comprising: transmittingPositioning Reference Signals (PRS) on the first and second carriers,the PRS transmissions staggered in time; and switching the primarycarrier for the UE to a carrier prior to a PRS transmission on thatcarrier.
 10. A method of positioning-aware carrier switching by UserEquipment (UE) operative in a multi-carrier wireless communicationnetwork, comprising: receiving communication signals on a first carrieras a primary carrier; performing one or more positioning measurements;receiving an indication from a serving node that the primary carrier isto be switched from the first carrier to a second carrier; and switchingto the second carrier as the primary carrier while preserving theongoing positioning measurements.
 11. The method of claim 10 furthercomprising receiving assistance data to perform positioning measurementson the second carrier.
 12. The method of claim 10 wherein switching tothe second carrier as the primary carrier while preserving the ongoingpositioning measurements comprises preserving the ongoing positioningmeasurements only if Positioning Reference Signals are transmitted onthe second carrier.
 13. The method of claim 10 wherein switching to thesecond carrier as the primary carrier while preserving the ongoingpositioning measurements comprises delaying the switch to the secondcarrier until the ongoing positioning measurements are complete.
 14. Themethod of claim 10 further comprising performing a positioning procedureusing the positioning measurements.
 15. The method of claim 10 furthercomprising transmitting the positioning measurements to a locationservices network node to perform a positioning procedure to position theUE.
 16. A serving node of a multi-carrier wireless communicationnetwork, comprising: a transceiver operative to simultaneously transmitto User Equipment (UE) communication signals modulated onto two or morecarriers, wherein a first carrier is designated as a primary carrier fora particular UE; and a controller operative to control the transceiver,and further operative to select a second carrier to be the primarycarrier for the UE, and to control the transceiver to switch the primarycarrier for the UE from the first carrier to the second carrier; whereinthe controller is further operative to constrain at least one of theselecting and switching operations so as to enable one or morepositioning measurements to be performed.
 17. The serving node of claim16 wherein switching the controller is operative to treat the carrierswitch as a handover procedure for an ongoing location service session.18. The serving node of claim 16 wherein the controller is operative toswitch the primary carrier for the UE from the first carrier to thesecond carrier by: ascertaining whether positioning measurements for theUE are ongoing; and delaying switching the primary carrier for the UEfrom the first carrier to the second carrier until the positioningmeasurements are complete.
 19. The serving node of claim 18 whereindelaying switching the primary carrier comprises delaying switching theprimary carrier only if the requested positioning Quality of Service(QoS) exceeds a predetermined QoS threshold.
 20. The serving node ofclaim 16 wherein the controller is operative to configure measurementgap information for the UE to align with positioning data transmissionson the second carrier.
 21. The serving node of claim 16 wherein thecontroller is operative to select a second carrier to be the primarycarrier for the UE by selecting a second carrier that transmitsPositioning Reference Signals (PRS).
 22. The serving node of claim 16wherein the controller is further operative to transmit PositioningReference Signals (PRS) on the second carrier if at least a firstpredetermined number of UEs are assigned the second carrier as a primarycarrier.
 23. The serving node of claim 16 wherein the controller isfurther operative to cease the transmission of Positioning ReferenceSignals (PRS) on the second carrier if fewer than a second predeterminednumber of UEs are assigned the second carrier as a primary carrier. 24.The serving node of claim 16 wherein the controller is further operativeto: transmit Positioning Reference Signals (PRS) on the first and secondcarriers, the PRS transmissions staggered in time; and switch theprimary carrier for the UE to a carrier prior to a PRS transmission onthat carrier.
 25. A User Equipment (UE) operative in a multi-carrierwireless communication network, comprising: a transceiver operative tosimultaneously receive from a network node communication signalsmodulated onto two or more carriers, wherein a first carrier isdesignated as a primary carrier for the UE; a position measurementfunction in data communications relationship to the transceiver andoperative to perform positioning measurements used in ascertaining ageographic location of the UE; and a controller operative to control thetransceiver and position measurement function, and further operative toswitch from the first carrier to a second carrier as the primary carrierin response to signals received from the network node, while preservingongoing positioning measurements.
 26. The UE of claim 25 wherein thecontroller is further operative to receive assistance data to performpositioning measurements on the second carrier.
 27. The UE of claim 25wherein the controller is further operative to use a pre-definedmeasurement gap pattern to perform positioning measurements.
 28. The UEof claim 25 wherein the controller is further operative to apply apredetermined rule to not use measurement gaps when PositioningReference Signals are transmitted on the second carrier.
 29. The UE ofclaim 25 wherein the controller is operative to preserve the ongoingpositioning measurements when switching to the second carrier as theprimary carrier only if Positioning Reference Signals are transmitted onthe second carrier.
 30. The UE of claim 25 wherein the controller isoperative to delay the switch to the second carrier until the ongoingpositioning measurements are complete.